Patent Grant
12214851
The present disclosure relates to apparatuses for supporting marine drives with respect to a marine vessel, in particular to such apparatuses having a copilot device.
The following are incorporated herein by reference, in entirety.
U.S. Pat. No. 9,205,906 discloses a mounting arrangement for supporting an outboard motor with respect to a marine vessel extending in a fore-aft plane. The mounting arrangement comprises first and second mounts which each have an outer shell, an inner wedge concentrically disposed in the outer shell, and an elastomeric spacer between the outer shell and the inner wedge. Each of the first and second mounts extend along an axial direction, along a vertical direction that is perpendicular to the axial direction, and along a horizontal direction which is perpendicular to the axial direction and perpendicular to the vertical direction. The inner wedges of the first and second mounts both have a non-circular shape when viewed in a cross-section taken perpendicular to the axial direction. The non-circular shape comprises a first outer surface that extends transversely at an angle to the horizontal and vertical directions. The non-circular shape comprises a second outer surface that extends transversely at a different, second angle to the horizontal and vertical directions. A method is for making the mounting arrangement.
U.S. Pat. No. 9,701,383 discloses a marine propulsion support system having a transom bracket, a swivel bracket, and a mounting bracket. A drive unit is connected to the mounting bracket by a plurality of vibration isolation mounts, which are configured to absorb loads on the drive unit that do not exceed a mount design threshold. A bump stop located between the swivel bracket and the drive unit limits deflection of the drive unit caused by loads that exceed the threshold. An outboard motor includes a transom bracket, a swivel bracket, a cradle, and a drive unit supported between first and second opposite arms of the cradle. First and second vibration isolation mounts connect the first and second cradle arms to the drive unit, respectively. An upper motion-limiting bump stop is located remotely from the vibration isolation mounts and between the swivel bracket and the drive unit.
U.S. Pat. No. 9,764,813 discloses a tiller for an outboard motor. The tiller comprises a tiller body that is elongated along a tiller axis between a fixed end and a free end. A throttle grip is disposed on the free end. The throttle grip is rotatable through a first (left handed) range of motion from an idle position in which the outboard motor is controlled at idle speed to first (left handed) wide open throttle position in which the outboard motor is controlled at wide open throttle speed and alternately through a second (right handed) range of motion from the idle position to a second (right handed) wide open throttle position in which the outboard motor is controlled at wide open throttle speed.
U.S. Pat. No. 11,097,824 discloses an apparatus for steering an outboard motor with respect to a marine vessel. The apparatus includes a transom bracket configured to support the outboard motor with respect to the marine vessel; a tiller for manually steering the outboard motor with respect to a steering axis; a steering arm extending above the transom bracket and coupling the tiller to the outboard motor such that rotation of the tiller causes rotation of the outboard motor with respect to the steering axis, wherein the steering arm is located above the transom bracket; and a copilot device configured to lock the outboard motor in each of a plurality of steering positions relative to the steering axis. The copilot device extends above and is manually operable from above the steering arm.
U.S. patent application Ser. No. 17/487,116 discloses an outboard motor including a transom clamp bracket configured to be supported on a transom of a marine vessel and a swivel bracket configured to be supported by the transom clamp bracket. A propulsion unit is supported by the swivel bracket, the propulsion unit comprising a head unit, a midsection below the head unit, and a lower unit below the midsection. The head unit, midsection, and lower unit are generally vertically aligned with one another when the outboard motor is in a neutral tilt/trim position. The propulsion unit is detachable from the transom clamp bracket.
U.S. patent application Ser. No. 17/509,739 discloses an apparatus for removably supporting a marine drive on a marine vessel. The apparatus has a transom bracket assembly for mounting to the marine vessel, a steering bracket for coupling the marine drive to the transom bracket assembly so the marine drive is steerable relative to the transom bracket assembly and the marine vessel; and an integrated copilot and locking mechanism configured to retain the steering bracket in a plurality of steering orientations. The mechanism is further configured to lock and alternately unlock the steering bracket relative to the transom bracket assembly such that in a locked position the marine drive is retained on the transom bracket assembly and such that in an unlocked position the marine drive is removable from the transom bracket assembly.
This Summary is provided to introduce a selection of concepts that are further described herein below in the Detailed Description. This Summary is not intended to identify key or essential features of the claimed subject matter, nor is it intended to be used as an aid in limiting scope of the claimed subject matter.
An apparatus is for supporting a marine drive on a marine vessel. The apparatus comprises a transom bracket having a swivel cylinder and a steering bracket configured to couple the marine drive to the transom bracket. The steering bracket has a steering arm and a swivel tube seated in the swivel cylinder. Steering of the steering arm relative to the transom bracket rotates the swivel tube in the swivel cylinder and thereby steers the marine drive. The apparatus has a novel copilot device configured to frictionally restrain rotation of the swivel tube in the swivel cylinder by applying diametrically opposing pushing and pulling forces on the swivel tube. Varying the diametrically opposing pushing and pulling forces varies a resistance to steering of the outboard motor relative to the transom bracket. In certain non-limiting embodiments, the copilot device is configured to apply the diametrically opposing pushing and pulling forces on at least half of an outer circumference of the swivel tube. In certain non-limiting embodiments, the copilot device is configured to apply the diametrically opposing pushing and pulling forces on at least three fourths of an outer circumference of the swivel tube.
In certain non-limiting embodiments, the copilot device has a friction head which applies the diametrically opposing pushing and pulling forces on the swivel tube. The friction head has first head portion and a second head portion which diametrically opposes the first head portion. The copilot device is configured to apply the diametrically opposing pushing and pulling forces on the swivel tube by increasingly pressing the first head portion on a first side of an outer circumference of the swivel tube and simultaneously increasingly pulling the second head portion on a diametrically opposite, second side of the outer circumference of the swivel tube.
In certain non-limiting embodiments, the copilot device further includes an actuator arm. Translation of the actuator arm in a first axial direction causes the friction head to increasingly apply said diametrically opposing pushing and pulling forces on the swivel tube. Translation of the actuator arm in an opposite, second axial direction causes the friction head to decreasingly apply said diametrically opposing pushing and pulling forces on the swivel tube.
In certain non-limiting embodiments, a release device is for automatically disengaging the copilot device from the swivel tube. The release device has a plunger located in the outer end of the actuator arm. Manually pressing the plunger causes the inner end of the actuator arm to automatically withdraw away from the outer circumference of the swivel tube. The plunger is retained in a locked position by a detent mechanism and wherein the plunger is spring biased towards an unlocked position.
Examples are described with reference to the following drawing figures. The same numbers are used throughout to reference like features and components.
Referring to
The steering arm 34 has a first end 44 which is fixed to a supporting frame or other component of the outboard motor 16, and an opposing second end 46 which is fixed to a conventional tiller handle 48, as illustrated in
As illustrated in
Referring to
The swivel tube 36 is seated in the cylindrical passage of the swivel cylinder 64 in a manner which facilitates steering rotation of the outboard motor 16 about the steering axis 76. Steering of the steering arm 34 relative to the transom bracket 54 rotates the swivel tube 36 within the swivel cylinder 64 and thereby steers the outboard motor 16 about the steering axis 76.
The above-described steering bracket 22 and transom bracket assembly 24 are generally configured like the embodiments disclosed in the presently incorporated U.S. Patent Application No. 17,509,739. However for the purposes of the present disclosure, it should be understood that the transom bracket assembly does not need to have a swivel bracket which is pivotable relative to a transom bracket. In other arrangements, the transom bracket assembly are a monolithic component or several components which are not pivotable about a trim axis. Reference is made to the above-incorporated U.S. patents and patent applications, which illustrate various other suitable arrangements facilitating pivoting movement of a swivel bracket relative to a transom bracket.
Presently incorporated U.S. Patent Application No. 17,509,739 discloses a copilot device for use with the above-described steering bracket 22 and transom bracket assembly 24. During research and development in this field, the present inventors determined it would be advantageous to improve upon the copilot device of the '739 application, in particular by increasing the circumferential area of frictional engagement between the copilot device and the steering tube. More specifically, the copilot device set forth in the '739 application is configured to frictionally engage (i.e., press against) one side of the swivel tube, which in some examples further presses the opposite side of the swivel tube against the side of the swivel cylinder. During research and development, the present inventors realized that it would be possible and in some situations advantageous to reconfigure the copilot device in such a way that both sides of the swivel tube are frictionally engaged in a clamping- or squeezing-type configuration. This was found to improve performance and reliability. The inventors also realized that frictionally engaging both sides of the swivel tube in a pushing/pulling (clamping or squeezing) configuration surprisingly maintains center alignment of the steering tube in the steering cylinder, along the steering axis, thus potentially enhancing useful life of the product. The inventors also realized that frictionally engaging both sides of the swivel tube advantageously helped reduce noise, vibration and harshness during use of the apparatus. The present disclosure is a result of the present inventor's realization of the above-described areas for improvement on known configurations and particularly their resulting efforts to provide improved copilot devices which better facilitate known copilot functionalities in accordance with the above.
The present figures illustrate embodiments of novel copilot devices according to the present disclosure, each of which is configured to frictionally restrain rotation of the swivel tube 36 within the swivel cylinder 64 by applying diametrically opposed pushing and pulling forces on the swivel tube 36, i.e., in a squeezing/clamping arrangement.
The friction head 100 has a first head portion 188 and a second head portion 190, which in the first embodiment are separate parts. The friction head 100 defines a receiving area 191 which surrounds the swivel tube 36. The first head portion 188 has an inner side 192 and an opposite outer side 194. A bore 196 extends into the outer side 194. The inner side 192 has an inner face having a curvature which generally matches the outer circumference of the swivel tube 36. As will be described below, the inner side 192 is configured to frictionally engage the outer circumference of the swivel tube 36 when the copilot device 80 is engaged.
The second head portion 190 has a mating portion 112 and a harness 110 which is integrally formed with the mating portion 112 via a first and a second arm 116, 118 extending therefrom. The mating portion 112 has a threaded through-bore 120 which is aligned with the bore 196 of the first head portion 188. The first arm 116 and the second arm 118 are located on radially opposing sides of the mating portion 112, respectively, and extend from opposing ends of the harness 110. The harness 110 extends peripherally about the swivel tube 36. The harness 110 has a curved inner face 115 which generally has the same curvature as the curved inner side of the first head portion 188 and is for frictionally engaging the outer circumference of the swivel tube 36 on an opposite side relative to the first head portion 188. The first head portion 188 is located between the mating portion 112 of the second head portion 190 and the swivel tube 36. As further described herein below, upon engagement of the copilot device 80, the first head portion 188 along the inner side 192 and the harness 110 of the second head portion 190 along the curved inner face 115 are diametrically pressed and pulled, respectively, onto opposite sides of the swivel tube 36 such that the copilot device 80 frictionally engages opposite sides of the swivel tube 36 and thus restrains steering of the outboard motor 16. Preferably the copilot device 80 frictionally engages at least half or more of the outer circumference 37 of the swivel tube 36 including its opposite sides, and even more preferably the copilot device 80 frictionally engages at least three fourths or more of the outer circumference 37 of the swivel tube 36 including its opposite sides.
The actuator arm 84 is manually rotatable about an engagement axis 81, which extends transversely from the steering axis 76. The actuator arm 84 has an inner end 83 and an outer end 85. The inner end 83 is threadingly engaged with the through-bore 120 on the second head portion 190 and protrudes into the bore 196 on the first head portion 188. The outer end 85 has a knob 87 which is manually rotatable. Rotation of the knob 87 rotates the actuator arm 84 relative to the friction head 100, which via the threaded connection causes second head portion 190 to travel along the actuator arm 84, such that the actuator arm 84 effectively moves inwardly or outwardly relative to the second head portion 190, depending on the direction of rotation. In other words, the axial location of the actuator arm 84 remains generally stationary relative to the housing 86, as the second head portion 190 moves inwardly or outwardly along the actuator arm 84, depending on the direction of rotation. In the illustrated example, rotation of the knob 87 in a first direction (e.g., clockwise) effectively causes the actuator arm 84 to move into the friction head 100. As the actuator arm 84 increasingly moves into the friction head 100, the inner end 83 of the actuator arm 84, via engagement with the bore 196, increasingly pushes the first head portion 188 towards the swivel tube 36. This causes the inner side 192 of the first head portion 188 to apply a corresponding pushing force on the swivel tube 36, i.e., radially toward the steering axis 76. Increasingly rotating the knob 87 in the first direction increases the frictional engagement between the first head portion 188 and the swivel tube 36 and thus increases the resistance to steering via the tiller handle 48.
Simultaneously upon rotation of the knob 87 in the first direction, the threaded engagement between the inner end 83 of the actuator arm 84 and the threaded through-bore 120 of the second head portion 190 causes the second head portion 190 to move outwardly relative to the outboard motor 16 along the actuator arm 84. This causes the curved inner face 115 to apply a corresponding diametrically opposing pulling force on the opposite side of the swivel tube 36, i.e., radially toward the steering axis 76, which is pulling force is opposed by the noted torque reaction force provided on the stem of the knob 87 by the fixed housing 86. Continued rotation of the actuator arm 84 increases the noted pulling force on the swivel tube 36 and thus increases the noted frictional restriction to steering rotation of the tiller handle 48.
The combination of pushing and pulling forces noted above thus effectively frictionally clamps or squeezes the swivel tube 36, providing an effective means for restraining steering of the outboard motor 16 advantageously without pushing the swivel tube 36 off center with respect to the swivel cylinder 64.
To disengage the copilot device 80, the actuator arm 84 is rotated in the opposite, second rotation direction (in this example, counter-clockwise) which causes the second head portion 190 to move in an opposite direction along the actuator arm 84. This decreases the noted diametrically opposing pushing and pulling forces applied on the swivel tube 36. More specifically, movement of the inner end 83 of the actuator arm 84 outwardly of the friction head 100 reduces the pushing force in the bore 196 of the first head portion 188 until the first head portion 188 no longer applies the pushing force on the side of the swivel tube 36. Simultaneously, the second head portion 190 moves along the actuator arm 84, toward the outboard motor 16, which reduces the noted pulling force until the second head portion 190 no longer applies the pulling force on the opposite side of the swivel tube 36. This frees the swivel tube 36 for rotation within the swivel cylinder 64 and thus facilitates less-restrained steering motion of the outboard motor 16. Thus, as illustrated in
Optionally, the copilot device 80 has an annular friction ring 49 which is located radially between the friction head 100 and the swivel tube 36. The friction ring 49 is made of a suitable material, such as polyurethane, and/or the like, for achieving a strong and durable frictional engagement on the outer circumference 37 of the swivel tube 36. Other suitable examples include any ceramic/metallic/polymer composite known for use in automotive and/or bicycle brake shoes/pads. Any material that provides a reasonable balance of friction coefficient and wear resistance will suffice. In some embodiments, there may be an advantage in using a non- or less-flexible material. In such embodiments, a break or breaks in the annular shape may be advantageous.
Like the first embodiment, the first head portion 188 has the inner side 192 which longitudinally opposes the outer side 194, and the bore 196 in the outer side 194. The inner side 192 has a curvature which generally matches the curvature of the second head portion 190. Similar to the first embodiment, the second head portion 190 has the mating portion 112 and the harness 110, which are formed integrally and connected via the first and the second arm 116, 118. The mating portion 112 has the threaded through-bore 120 which is aligned with the bore 196 of the first head portion 188. The first and second arms 116, 118 extend from radially opposing ends of the mating portion 112, adjacent opposite sides of the swivel tube 36, respectively, and are coupled to opposing ends of the harness 110. The harness 110 extends around the swivel tube 36. The harness 110 has the curved inner face 115 with a curvature which is generally same as radial curvature of the curved inner side 192 of the first head portion 188. The actuator arm 84 is threadingly engaged at the inner end 83 with the threaded through-bore 120 on the second head portion 190 and passes through and extends into the bore 196 on the first head portion 188. Like the first embodiment, the first head portion 188 and second head portion 190 are configured to frictionally engage opposite sides of the swivel tube 36, preferably at least half of the outer circumference 37 of the swivel tube 36 or more, and more preferably at least three fourths of the outer circumference 37 of the swivel tube 36 or more.
In use, as illustrated in
During further research and development, the present inventors also realized it would be advantageous to provide a copilot device with a quick release functionality, in particular which permits quick release of the frictional engagement from the copilot device on the swivel tube, without requiring manual (counter clockwise) rotation of the handle. The third embodiment shown in
Referring to
Unlike the first embodiment, the actuator arm 84 is automatically releasable from the engaged position via a novel quick release mechanism 386. As shown in
The quick release mechanism 386 has a plunger 319, a compression spring 341, and a pair of detent balls 343. The plunger 319 is telescopically movable within the outer end 325 of the engagement arm 317. The plunger 319 has an inner end 333 located in the engagement arm 317 and an outer end 335 which protrudes from the outer end 325 of the engagement arm 317. The spring 341 tends to expand and thus biases the inner end 333 of the plunger 319, outwardly relative to the outer end 325 of the engagement arm 317. A push head 337 is on the outer end 335 and is configured for pushing by an operator's thumb.
Referring to
Referring to
To unlock the quick release mechanism 315, as shown in
In the present description, certain terms have been used for brevity, clarity, and understanding. No unnecessary limitations are to be implied therefrom beyond the requirement of the prior art because such terms are used for descriptive purposes only and are intended to be broadly construed. The different apparatuses described herein may be used alone or in combination with other apparatuses. Various equivalents, alternatives and modifications are possible within the scope of the appended claims.
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